Booklet reading device

ABSTRACT

A document reading device ( 1 ) comprises a mounting surface ( 5 ) on which a page to be read ( 9 ) of a passport ( 7 ) is placed, a camera ( 13 ) for taking an image of the page to be read ( 9 ), an illumination light source ( 15 ) for radiating illumination light that will be reflected on the page to be read ( 9 ), and an ultraviolet light source ( 41 ) for radiating ultraviolet light to activate a fluorescent material on the page to be read ( 9 ). The illumination light source ( 15 ) is located at a position corresponding to a first edge ( 73 ) perpendicular to a binding edge ( 71 ) on the page to be read ( 9 ) and radiates illumination light in the direction intersecting with the first edge ( 73 ). The ultraviolet light source ( 41 ) is located at a position corresponding to a second edge ( 75 ) parallel to the binding edge ( 71 ) and arranged to radiate ultraviolet light in the direction intersecting with the second edge ( 75 ). The illumination light source ( 15 ) includes an infrared light source ( 21 ) and a white light source ( 31 ). A document reading device is thus provided, which is provided with both an illumination light source and an ultraviolet light source, and can avoid image capturing in the specular reflection condition when the document is deformed, while the size of the device can be reduced.

TECHNICAL FIELD

The present invention relates to a document reading device for capturingan image of a surface to be read, and more particularly to anarrangement of light sources for image capturing.

BACKGROUND ART

Conventionally, a document reading device is known for reading a codesuch as characters from a document. The document is composed of boundsheets. The document is, for example, a passport.

In a document reading device, a document is placed on a glass plate orthe like, and a surface to be read is irradiated with illumination lightto capture an image of the surface to be read. In the case where thedocument is a passport, for example, the surface to be read is a pagecarrying a photograph and the passport number. Visible light or infraredlight is used as the illumination light.

The visible light is typically white light and is suitable for use inobtaining an image of the surface to be read as in an image scanner. Theimage is displayed on a monitor, for example.

The infrared light is suitable for reading processing such as opticalcharacter recognition. In an infrared image, background images tend tobe unclear and the image has high contrast of a code such as characters.This, therefore, allows accurate reading processing.

The visible light and infrared light are an illumination light sourceand reflection is used. In other words, illumination light such asvisible light and infrared light is reflected on the surface to be readand the reflected light is incident upon an imaging unit. In contrast,there is an ultraviolet light source as a light source which does notuse reflection.

When an ultraviolet light source is used, shapes are drawn by means of afluorescent material. When the surface to be read is irradiated withultraviolet light, the fluorescent material is activated. The imagingunit generates an image with visible light emitted from the fluorescentmaterial. The ultraviolet light source is used to prevent illegal actssuch as tampering.

A reading device that uses illumination light is disclosed, for example,in Patent Literature 1. A reading device provided with an ultravioletlight source is disclosed, for example, in Patent Literature 2.

In conventional document reading devices, however, the device sizeincreases when the illumination light source and the ultraviolet lightsource coexist. In this respect, in recent years, there has been anincreasing need for functional improvement of reading devices. If two ormore kinds of light sources are to be provided in order to satisfy theneed, the space occupied by the light sources increases accordingly. Inparticular, if both a visible light source and an infrared light sourceare to be provided as illumination light sources, three light sourcesare required: visible light source, infrared light source, andultraviolet light source. This requires even larger space. Further, inrecent years, LED elements have been preferred as light sources. If twoor more kinds of LED elements are to be arranged in order to provideillumination light and ultraviolet light, the number of elements, andtherefore the space occupied by an array of elements, increasesaccordingly.

In addition, a document such as a passport is likely to curl or lift,which may cause a specular reflection condition as a lighting condition.The specular reflection condition means that the orientation of an imageto be captured coincides with the direction of the specular reflectionof illumination light. In the specular reflection condition, reflectedlight may be too strong when an image of the surface to be read iscaptured. As a result, a so-called “washed-out highlight” appears in thevisible light image and a good image cannot be obtained. The “washed-outhighlight” is a phenomenon that occurs when light incident upon animaging device is so strong that the dynamic range of the device isexceeded and a part of image is washed out, leaving a blurred image thatis whitish and without an object. In the case of infrared light,contrast of characters and the like similarly decreases and readabilitydecreases when an image is captured in the specular reflectioncondition. Therefore, it is necessary to avoid the specular reflectioncondition for illumination light such as visible light and infraredlight. In particular, it is important to avoid the specular reflectioncondition for a passport and the like because many of them are coveredwith a laminate film or the like and have high reflectance.

Conventionally, the surface to be read is illuminated from the side andan image of the surface to be read is captured directly in front. Inthis way, the reflection angle (=incident angle) of illumination lightcan be increased to avoid the specular reflection condition.

However, if deformation of a document such as curl or lift occurs, theangle of the surface to be read may vary and cause the specularreflection condition. Therefore, it is required to be able to avoid thespecular reflection condition even if deformation of a document occurs.

To avoid problems described above, a conventional copier or the like isprovided with a cover for pressing an object to be read. When thedocument is a passport or the like, however, it must be read rapidly.Therefore, it is desirable to appropriately illuminate the documentwithout a cover or the like even if the document floats to some extent.

CITATION LIST Patent Literature

-   Patent Literature 1: Japanese Patent Laid-Open No. H06-247084-   Patent Literature 2: Japanese Patent Laid-Open No. S58-142486

SUMMARY OF INVENTION Technical Problem

The present invention has been made under such circumstances. It is anobject of the invention to provide a document reading device, which isprovided with both a illumination light source and an ultraviolet lightsource, and can avoid image capturing in the specular reflectioncondition when the document is deformed, while the size of the devicecan be reduced.

Solution to Problem

One aspect of the invention is a document reading device, and thedocument reading device comprises: a document placing unit on which asurface to be read of a document is placed, the document being composedof a plurality of sheets bound at a binding edge; an imaging unit fortaking an image of the surface to be read; an illumination light sourcefor radiating illumination light to illuminate the surface to be read;an ultraviolet light source for radiating ultraviolet light to activatea fluorescent material on the surface to be read; wherein theillumination light source is located at a position corresponding to afirst edge perpendicular to the binding edge on the surface to be readand arranged to radiate illumination light toward the surface to be readin a direction intersecting with the first edge, and the ultravioletlight source is located at a position corresponding to a second edgeparallel to the binding edge on the surface to be read and arranged toradiate ultraviolet light toward the surface to be read in a directionintersecting with the second edge.

As described below, the present invention has other aspects. Therefore,the disclosure of the invention is intended to provide some of theaspects of the invention, and is not intended to limit the scope of theinvention as described and claimed herein.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a cross-unital view of a document reading device according toan embodiment.

FIG. 2 is a cross-unital view of a document reading device according tothe embodiment, which shows a light source arrangement.

FIG. 3 is a cross-unital view of a document reading device according tothe embodiment, which shows a light source arrangement.

FIG. 4 is a perspective view of a document reading device according tothe embodiment.

FIG. 5 shows a page to be read of a passport, which is a page to beread.

FIG. 6 shows an ultraviolet light source.

FIG. 7 shows a deformed passport.

FIG. 8 shows the principle of the present invention for preventing awashed-out highlight at a code location when a wave-like deformationoccurs in the passport.

DESCRIPTION OF EMBODIMENTS

The present invention will now be described in detail. However, thedetailed description below and attached drawings are not intended tolimit the present invention. Rather, the scope of the invention isdefined by the attached claims.

A document reading device according to the present invention comprises:a document placing unit on which a surface to be read of a document isplaced, the document being composed of a plurality of sheets bound at abinding edge; an imaging unit for taking an image of the surface to beread; an illumination light source for radiating illumination light toilluminate the surface to be read; an ultraviolet light source forradiating ultraviolet light to activate a fluorescent material on thesurface to be read; wherein the illumination light source is located ata position corresponding to a first edge perpendicular to the bindingedge on the surface to be read and arranged to radiate illuminationlight toward the surface to be read in a direction intersecting with thefirst edge, and the ultraviolet light source is located at a positioncorresponding to a second edge parallel to the binding edge on thesurface to be read and arranged to radiate ultraviolet light toward thesurface to be read in a direction intersecting with the second edge.

With this configuration, the illumination light source and theultraviolet light source are provided at positions corresponding to thefirst edge and the second edge, respectively. In this way, the size ofdevice can be reduced because, instead of disposing a large light sourceat one place, smaller light sources are disposed at two or morelocations. In addition, according to the invention, the relationshipbetween deformation of the document and the specular reflectioncondition is taken into consideration in determining the light sourcearrangement. When the document curls or lifts, the second edge is likelyto float and the angle of the surface to be read varies largely in thedirection intersecting with the second edge. In the directionintersecting with the first edge, however, the angle of the surface tobe read is less likely to vary. The illumination light source istherefore arranged to radiate illumination light in the directionintersecting with the first edge so as to be able to avoid imagecapturing in the specular reflection condition caused by the deformationof the document. On the other hand, ultraviolet light is less likely tohave the problem of the specular reflection condition because theultraviolet light is used for fluorescent activation. The ultravioletlight source is therefore disposed at a position corresponding to thesecond edge. In this way, according to the invention, the illuminationlight source and the ultraviolet light source are separately arrangedwhile the relationship between deformation of the document and thespecular reflection condition is taken into consideration. As a result,image capturing in the specular reflection condition can be avoided whenthe document is deformed, while the size of device can be reduced.

Further, in the document reading device according to the invention, theillumination light source may include a visible light source. With thisconfiguration, a document reading device can be provided, which isprovided with both a visible light source and an ultraviolet lightsource, and can avoid image capturing in the specular reflectioncondition when the document is deformed, while the size of the devicecan be reduced. The visible light source is, for example, a white lightsource.

Further, in the document reading device according to the invention, theillumination light source may include an infrared light source. Withthis configuration, a document reading device can be provided, which isprovided with both an infrared light source and an ultraviolet lightsource, and can avoid image capturing in the specular reflectioncondition when the document is deformed, while the size of the devicecan be reduced.

Further, in the document reading device according to the invention, theillumination light source may include both a visible light source and aninfrared light source, and the visible light source may be locatedfarther away from the surface to be read in the vertical direction thanthe infrared light source.

With this configuration, a visible light source, an infrared lightsource, and an ultraviolet light source are provided. In addition, thevisible light source is located farther away from the surface to be readin the vertical direction than the infrared light source. Since theinfrared light source is located closer to the surface to be read, alarger area can be illuminated even with the infrared light source thathas a narrow radiation angle, and readability can be assured. Inaddition, since the visible light source is located away from thesurface to be read, the difference between the distance from onelocation on the surface to be read to the visible light source and thedistance from another location to the visible light source is reduced,so that unevenness of illumination is also reduced and a good displayimage can be obtained. Therefore, a document reading device can beprovided, which is provided with a visible light source, an infraredlight source, and an ultraviolet light source, and can avoid imagecapturing in the specular reflection condition when the document isdeformed, while the size of the device can be reduced and the device iscapable of appropriately providing both visible and infrared lightillumination.

Further, in the document reading device according to the invention, theimaging unit may have a UV cut filter. With this configuration,ultraviolet light reflecting or otherwise coming from the ultravioletlight source can be prevented from entering the imaging unit, and imagequality obtained by the imaging unit can be improved.

According to the invention, since the illumination light source and theultraviolet light source are appropriately disposed with respect to thefirst edge and the second edge as described above, which areperpendicular to each other, image capturing in the specular reflectioncondition can be avoided when the document is deformed, while the sizeof device can be reduced.

A document reading device according to embodiments of the presentinvention will now be described below with reference to drawings.

In an embodiment, the document is a passport. In addition, theillumination light source is a white light source and an infrared lightsource. The white light source is an example of a visible light source.

A document reading device according to the embodiment of the inventionis shown in FIGS. 1 to 4. FIGS. 1 to 3 are cross-unital views and FIG. 4is a perspective view.

Referring first to FIG. 4, a document reading device 1 has asubstantially cubic housing 3, which is provided with a mounting surface5 on the top. The mounting surface 5 is a transparent glass plate. Themounting surface 5 is a place on which a passport 7, which is an objectto be read, is placed and corresponds to a document placing unit of theinvention. The housing 3 is also provided with stop units 51 and 53,which are perpendicular to each other. The stop units 51 and 53 have astop wall. Two sides of the passport 7 meeting at a right angle restagainst the stop units 51 and 53, and the passport 7 is therebypositioned on the mounting surface 5.

FIG. 5 schematically shows the passport 7. As described above, thepassport 7 is a kind of document and composed of a plurality of sheetsbound in the middle.

The passport 7 has a page to be read 9. The page to be read 9corresponds to a surface to be read of the invention. The page to beread 9 has a photograph 61, a code 63, and a fluorescent pattern 65. Thecode 63 is a string of characters and the like to be read by thedocument reading device 1. In the passport 7, the code 63 is providedalong a second edge 75. The fluorescent pattern 65 is made of afluorescent material. The page to be read 9 is also covered with alaminate film or the like. The passport 7 is placed on the mountingsurface 5 with the page to be read 9 facing downward.

The page to be read 9 also has a first edge 73 and second edge 75. Thefirst edge 73 is an edge perpendicular to a binding edge 71 and thesecond edge 75 is an edge parallel to the binding edge 71. The firstedge 73 and the second edge 75 meet at a right angle to each other.

In the passport 7, the page to be read 9 is a page on one side to thebinding edge 71. As shown in the figure, therefore, two short sides orshort edges on opposite sides of the page to be read 9 correspond tofirst edges 73. Similarly, long sides or long edges of the page to beread 9 are second edges 75, and the binding edge 71 itself is a secondedge 75.

FIG. 1 is a cross-unital view of the document reading device 1 takenalong a line A-A in FIG. 4. FIG. 2 shows a light source arrangement whenviewed in the same direction as in FIG. 1, and FIG. 3 shows the lightsource arrangement of FIG. 2 when viewed in the direction of an arrow B.

As shown in FIG. 1, a mirror 11 is provided below the mounting surface5, and a camera 13 is provided to the side of the mirror 11. The camera13 corresponds to an imaging unit of the invention. The camera 13 isprovided with a UV cut filter (UV filter). The camera 13 uses areflection of the mirror 11 to capture an image of the passport 7 fromunderneath. The camera 13 may capture both an infrared light image and avisible light image. Alternatively, an infrared light image and avisible light image can be captured by separate cameras. In this case,the imaging unit is composed of two or more cameras.

As shown in FIGS. 1 to 3, the document reading device 1 also has anillumination light source 15 and an ultraviolet light source 41 in thehousing 3, and the illumination light source 15 consists of an infraredlight source 21 and a white light source 31. The white light source 31corresponds to a visible light source of the invention.

The infrared light source 21 is composed of an infrared LED array 23,and the infrared LED array 23 consists of a plurality of infrared LEDs25 a to 25 e. Similarly, the white light source 31 is composed of awhite LED array 33, and the white LED array 33 consists of a pluralityof white LEDs 35 a to 35 f. The infrared LEDs 25 a to 25 e and the whiteLEDs 35 a to 35 f are mounted on a circuit board 55.

The ultraviolet light source 41 is composed of an ultraviolet LED array43, and the ultraviolet LED array 43 consists of a plurality ofultraviolet LEDs 45 a to 451. As shown in FIGS. 1 and 6, the ultravioletLEDs 45 a to 451 are mounted on a circuit board 57, and the circuitboard 57 is secured in the housing 3.

As shown in FIG. 3, the illumination light source 15 is arranged toradiate illumination light (white light and infrared light) toward thepage to be read 9 in the direction intersecting with the first edge 73from a position both outside a front area of the page to be read 9 andoutside the two first edges 73. The ultraviolet light source 41 isarranged to radiate ultraviolet light toward the page to be read 9 inthe direction intersecting with the second edge 75 from a position bothoutside a front area of the page to be read 9 and outside the two secondedges 75.

As shown in FIGS. 1 to 3, in the illumination light source 15, the whitelight source 31 (white LED array 33) is basically located farther awayfrom the page to be read 9 in the vertical direction than the infraredlight source 21 (infrared LED array 23). Here, the vertical direction isa direction vertical to the page to be read 9 placed on the mountingsurface 5, that is, a direction vertical to the mounting surface 5. Inthe embodiment, a second distance D2 in the vertical direction from thepage to be read 9 to the white light source 31 is larger than a firstdistance D1 in the vertical direction from the page to be read 9 to theinfrared light source 21 (FIG. 3).

In the white LED array 33, however, an endmost white LED 35 f farthestfrom the binding edge 71 is exceptionally located closer to the page tobe read 9 in the vertical direction than other white LEDs 35 a to 35 e.Specifically, the endmost white LED 35 f is located next to an endmostinfrared LED 25 e in the infrared LED array 23.

The operation of the document reading device 1 according the embodimentwill be described. A user first places the passport 7 on the mountingsurface 5 with the page to be read 9 facing downward. The first edge 73and the second edge 75 of the passport 7 rest against the stop units 53and 51, respectively, and the passport 7 is thereby positioned. Inresponse to user operation, an image of the page to be read 9 iscaptured.

In reading processing, the page to be read 9 is irradiated with infraredlight by the infrared light source 21 and an infrared light image isgenerated by the camera 13. The infrared light image is then processedby a reading processing unit, not shown, to recognize a code such ascharacters. In an infrared light image, since a substantial amount ofinfrared light is absorbed by black ink, background images tend to berelatively unclear and the image has enhanced contrast of a code such ascharacters to be recognized. This, therefore, allows accurate readingprocessing. The reading processing unit may be composed of a computer.Further, the reading processing unit may be located outside the documentreading device 1.

To obtain a display image, the page to be read 9 is irradiated withwhite light by the white light source 31 and a visible light image isgenerated by the camera 13. The visible light image is then displayed ona monitor, not shown.

When the fluorescent pattern 65 is used to prevent illegal acts such astampering, the page to be read 9 is irradiated with ultraviolet light bythe ultraviolet light source 41 to activate a fluorescent material inthe fluorescent pattern 65 on the page to be read 9. The camera 13 thengenerates an image with visible light emitted from the fluorescentmaterial. An image of the fluorescent pattern 65 thus obtained may alsobe output and displayed on a monitor, not shown. The image of thefluorescent pattern 65 may also be compared with a registered image todetermine illegal acts. The determination may be performed either withinor outside the document reading device 1.

An arrangement of the illumination light source 15 (the infrared lightsource 21 and the white light source 31) and the ultraviolet lightsource 41 according to the embodiment will now be described in detail.In the embodiment, items (1) to (3) below are taken into considerationto define the light source arrangement.

(1) In the embodiment, the illumination light source 15 is located at aposition corresponding to the first edge 73 and the ultraviolet lightsource 41 is located at a position corresponding to the second edge 75.More specifically, a pair of illumination light sources 15 are locatedoutside opposite first edges 73 with the page to be read 9 between theillumination light sources 15. A pair of ultraviolet light sources 41are located outside opposite second edges 75 with the page to be read 9between the illumination light sources 15.

In this way, the illumination light source 15 and the ultraviolet lightsource 41 are disposed at different locations with respect to the firstedge 73 and the second edge 75 meeting at a right angle to each other.The illumination light source 15 and the ultraviolet light source 41 arenot found at the same location. Therefore, the size of device can bereduced because, instead of disposing a large light source at one place,smaller light sources are disposed at two or more locations.

In particular, in the embodiment, the illumination light source 15includes the infrared light source 21 and the white light source 31. Inaddition, each of the infrared light source 21, the white light source31, and the ultraviolet light source 41 is composed of an LED array.This requires a number of LED elements to be provided. Without collectedon one place, such a number of LED elements can be allocated to thefirst edge 73 and the second edge 75. Therefore, increase in the devicesize can be avoided.

(2) The illumination light source 15 is also located at a positioncorresponding to the first edge 73 and arranged to radiate illuminationlight toward the page to be read 9 in a direction intersecting with thefirst edge 73. More specifically, the central axis of the illuminationlight is intersecting at a right angle with the first edge 73. Thecentral axis of the illumination light, however, may not beperpendicular to the first edge 73 and may be oblique within the scopeof the invention.

Such an arrangement of the illumination light source 15 is advantageousto avoid the specular reflection condition. As discussed above, thespecular reflection condition means that the orientation of an image tobe captured coincides with the direction of the specular reflection ofillumination light. In the specular reflection condition, reflectedlight may be too strong when an image of the page to be read 9 iscaptured. As a result, a so-called “washed-out highlight” appears in thevisible light image and a good image cannot be obtained.

In order to avoid the specular reflection condition, it is advantageousto increase an incident angle (=reflection angle). By doing this,reflected light can be prevented from proceeding toward the mirror 11below. In the embodiment, therefore, as shown in FIG. 2, theillumination light source 15 is located at a position outside a frontarea of the page to be read 9 and illuminates the page to be read 9 fromthe side.

A document such as the passport 7 is likely to curl or lift and islikely to float in its nature. If the document floats, the angle betweenthe page to be read 9 and the illumination light source 15 may vary andcause the specular reflection condition. The embodiment takes the factinto consideration to avoid the specular reflection condition.

As shown in FIG. 7, the deformation of the passport 7 is likely to occurin the page-turning direction. The deformation forces the page to beread 9 into a cylindrical curved surface. In this case, the second edge75 floats. Accordingly, the angle of the page to be read 9 varieslargely in the direction perpendicular to the second edge 75. However,the first edge 73 exhibits almost no float. Then, the angle of the pageto be read 9 exhibits almost no change in the direction perpendicular tothe first edge 73. This is because, in the cylindrical surface resultingfrom deformation, an axial line should be straight.

If the illumination light source 15 is located at a positioncorresponding to the second edge 75 and the deformation occurs asdescribed above, the incident angle decreases and it is therefore likelyto cause the specular reflection condition.

In the embodiment, however, the illumination light source 15 is locatedat a position corresponding to the first edge 73, more specifically,outside the first edge 73. In addition, the illumination light source 15radiates illumination light in the direction intersecting with the firstedge 73.

Therefore, even when the passport 7 deforms, the angle between the pageto be read 9 and the illumination light source 15 does not vary largelyso that the specular reflection condition can be avoided.

To avoid the problem of deformation described above, a conventionalcopier or the like is provided with a cover for pressing an object to beread. However, since the passport 7 is read at a location such asimmigration and customs, readiness is essential. Pressing the passport 7with the cover every time is therefore time-consuming. Contrarily, asshown in FIG. 1, the document reading device 1 according to theembodiment does not require a pressing cover so that the passport 7 canbe set on the mounting surface 5 quickly.

(3) On the other hand, the ultraviolet light source 41 is located at aposition corresponding to the second edge 75. The ultraviolet lightsource 41 is used to activate a fluorescent material. When theultraviolet light source 41 is used, the camera 13 captures visiblelight emitted from the fluorescent material. Therefore, reflectedultraviolet light is not used in image capturing and is essentiallyindependent from the problem of specular reflection condition. Further,in the embodiment, the camera 13 is provided with a UV filter to cutultraviolet light.

Consequently, since the specular reflection condition may not need to betaken into consideration for ultraviolet light, the ultraviolet lightsource 41 is disposed with respect to the second edge 75.

In summary of the items (1) to (3) above, in the embodiment, theillumination light source 15 and the ultraviolet light source 41 aredifferently arranged while the specular reflection condition occurringwhen the passport 7 deforms is taken into consideration. Theillumination light source 15 is then disposed with respect to the firstedge 73 so as to avoid the specular reflection condition even when thepassport 7 deforms. The ultraviolet light source 41 is disposed withrespect to the second edge 75 because the specular reflection conditioncan be ignored. In this way, the illumination light source 15 and theultraviolet light source 41 are separately arranged so as to be able toreduce the size of the device while avoiding the specular reflectioncondition.

Referring to items (A) to (C) below, arrangements of the infrared lightsource 21 and the white light source 31 in the illumination light source15 will now be described in detail. The infrared light source 21 islocated at a first distance D1 from the page to be read 9 and the whitelight source 31 is located at a second distance D2 from the page to beread 9; the second distance D2 is larger than the first distance D1. Inother words, the infrared light source 21 is located close to the pageto be read 9 and the white light source 31 is located away from the pageto be read 9.

(A) Description will first be made to the setting of the first distanceD1 from the page to be read 9 to the infrared light source 21. Theinfrared light source 21 reads, for example, the code 63 shown in FIG.5. The code 63 is provided along a second edge 75.

In contrast, the infrared LEDs 25 a to 25 e of the infrared light source21 have a narrow wavelength band and a narrow radiation angle. Asdescribed above, a radiation angle refers to a range in which thebrightness of illumination light is at or above a predetermined level.The radiation angle is defined as, for example, a range of angle inwhich the brightness is at or above a predetermined percentage relativeto a reference value that is defined as a brightness directly in front.Because of the narrow radiation angle, if the first distance D1 is largeand the infrared light source 21 is located away from the page to beread 9, an area away from the infrared light source 21 can be irradiatedwhile an area close to the infrared light source 21 cannot beirradiated, and readability may be degraded. The first distance D1 istherefore set to a distance in which the entire code 63 including anarea close to the infrared light source 21 can be irradiated andreadability can be assured.

(B) Next, an arrangement of the white light source 31 will be described.The arrangement of the white light source 31 is set in consideration ofitems (B1) and (B2) below.

(B1) The brightness of white light varies largely depending on thedistance from the white light source 31. If the distance D2 from thepage to be read 9 to the white light source 31 is small, the distancebetween one location on the page to be read 9 and the white light source31 may be largely different from the distance between another locationand the white light source 31, which causes unevenness of illuminationand also unevenness in an image. Specifically, the center portion of thepage to be read 9 is slightly darker because of the larger distance fromthe white light sources 31 on opposite sides. The second distance D2 istherefore set to a distance in which the unevenness can be reduced andrequired image qualify can be obtained. As a result, the distance D2 isdefined as being larger than the distance D1, and therefore, the whitelight source 31 is located farther away from the page to be read 9 thanthe infrared light source 21.

(B2) The passport 7 often has the page to be read 9 covered with atransparent laminate film or the like and is provided with a lightdiffracting pattern on the front, on the back, or within the inside ofthe laminate film in order to detect a fraud. In addition, as describedabove, a document such as the passport 7 is likely to curl or lift inits edge and is therefore likely to float above the document readingdevice 1 in its nature.

When such passport 7 is illuminated, infrared light illumination withnarrow wavelength band is less likely to be affected. However, visiblelight illumination with wide wavelength band may be affected.Specifically, if the white light source 31 was located close to the pageto be read 9, an unintended pattern such as a rainbow would appear on acaptured image due to the laminate film or the diffracting structure, sothat a good image could not be obtained and the image displayed on themonitor might be difficult to view. In the embodiment, therefore, thedistance D2 for the white light source 31 is set to a distance in whichan unintended shape is less likely to appear on an image even when thepassport 7 is floating above the mounting surface 5. As a result, thesecond distance D2 is defined as being larger than the first distanceD1, and the white light source 31 is located farther away from the pageto be read 9 than the infrared light source 21.

(C) Next, an arrangement of the white LED 35 f on an end of the whitelight source 31 will be described. The arrangement of the white LED 35 fis associated with the position of the code 63 on the page to be read 9.As described above, the code 63 is provided along a second edge 75 nearthe second edge 75 of the page to be read 9. An end of the code 63 is inclose proximity to the first edge 73 of the page to be read 9 and islocated at a corner of the page to be read 9.

The white LED 35 f is located at the farthest end of the white LED array33, where corresponds to the code 63 in the direction of the array. Thewhite LED 35 f is located at a position higher, that is, closer to thepage to be read 9 in the vertical direction than other white LEDs 35 ato 35 e. Specifically, the white LED 35 f is at the same height as theinfrared LED array 23. The arrangement has advantages as describedbelow.

The passport 7 may often be held in a pocket of an owner and may be wetwith sweat of the owner. Wetted by sweat and subsequently dried, amongother causes, the passport 7 may have a wave-like deformation(corrugation) in its edge. The first edge 73 may be on the bottom in thepocket, and the wave-like deformation is likely to occur in the firstedge 73.

The wave-like deformation causes cyclical increase and decrease in theangle between the page to be read 9 and the white light source 31. In alarger angle area, the incident angle (=angle of emergence) is reducedand locally causes the specular reflection condition. Consequently, thewave-like deformation causes the specular reflection condition along thefirst edge 73 in a cyclical manner. As a result, as shown in the lefthalf of FIG. 8, a plurality of spaced-apart, small washed-out areasappear along the first edge 73. Depending on the shape of the waves, thewashed-out area coincides the code 63 as shown, and an end of the code63 may be hidden by the washed-out area. This blurs the end of the code63 in an image generated with the white light source 31. In particular,a few characters on the end of the code 63 are likely to blur.

The code 63 is an object to be automatically read with the infraredlight source 21. Even in a visible light image captured by means of thewhite light source 31, the entire code 63 should be displayed in orderto verify the result of reading or for other purposes. Therefore, thewashed-out highlight phenomenon described above should be prevented.

In order to attain such objects, in the embodiment, the white LED 35 ffound at a position corresponding to the code 63 is located closer tothe page to be read 9 locally. In this way, the incident angle (=angleof emergence) of white light becomes larger at the position of the code63 than other positions. Consequently, even if the angle of the page tobe read 9 in its corner varies due to deformation, the incident anglemay not be too small and the specular reflection condition can beavoided. As a result, as shown in the right half of FIG. 8, thewashed-out highlight is prevented from appearing at the positioncorresponding to the code 63.

Here, since the radiation range of the white LED 35 f reduces when thewhite LED 35 f is brought closer to the page to be read 9, there is aconcern of unevenness in the illuminance. In the embodiment, however,only the white LED 35 f is in a different position locally. With widerradiation angles, since other white LEDs 35 a to 35 e illuminate theentire area of the page to be read 9, an unevenness in the illuminanceintense enough to affect an image may not occur.

As shown in FIG. 8, washed-out highlights remain at locations withoutthe code 63. As compared with the code 63, however, other areas are muchless important. In the embodiment, therefore, washed-out highlights inless important areas are considered as being acceptable and a good imageof the code 63 area is obtained.

Next, variations of the item (C) above will be described. The code 63described above is an example of a near-edge code. A near-edge codeherein is a code located close to an edge of an object to be read.Specifically, a near-edge code is a code located close to an edge on theside of a light source used for obtaining a display image, and at leasta part of the code is located close to the edge. In case of a passport 7as the object to be read, the near-edge code is located at an end of anedge, and an endmost white LED is in proximity to the object to be read.However, depending on the type of the object to be read, the position orthe like of the near-edge code may vary, and therefore the light sourcearrangement may vary accordingly.

For example, the near-edge code may be centered on an edge. In thiscase, in agreement with the near-edge code, a white LED corresponding tothe center of the edge is brought closer to the object to be read.

Further, two or more white LEDs may be brought closer to an object to beread for one near-edge code. In other words, at least one white LEDs maybe brought closer to the object to be read within the scope of theinvention. A white LED(s) that should be brought closer to an object tobe read may be determined depending on spacing between elements and thewidth of a code.

Further, a near-edge code may not necessarily be located at oneposition. Two or more near-edge codes may be provided. In this case, twoor more white LEDs may be brought closer to an object to be read at twoor more respective positions.

Further, two or more near-edge codes may each have a different purpose,significance, use, importance, or the like. Therefore, the position ofonly a white LED corresponding to a necessary near-edge code may bechanged.

A document reading device 1 according to an embodiment of the presentinvention have been described. According to the embodiment, theillumination light source 15 is located at a position corresponding tothe first edge 73 perpendicular to the binding edge 71 on the surface tobe read and arranged to radiate illumination light toward the surface tobe read in the direction intersecting with the first edge 73. Theultraviolet light source 41 is located at the position corresponding tothe second edge 75 parallel to the binding edge 71 on the surface to beread and arranged to radiate ultraviolet light toward the surface to beread in the direction intersecting with the second edge 75. Therefore,the size of device can be reduced because, instead of disposing a largelight source at one place, smaller light sources are disposed at two ormore locations.

In addition, according to the invention, the relationship betweendeformation of the document and the specular reflection condition istaken into consideration in determining the light source arrangement.When the document curls or lifts, the second edge 75 is likely to floatand the angle of the surface to be read varies largely in the directionintersecting with the second edge 75. In the direction intersecting withthe first edge 73, however, the angle of the surface to be read is lesslikely to vary. The illumination light source 15 is therefore arrangedto radiate illumination light in the direction intersecting with thefirst edge 73 so as to be able to avoid image capturing in the specularreflection condition caused by the deformation of the document. On theother hand, ultraviolet light is less likely to have the problem of thespecular reflection condition because the ultraviolet light is used forfluorescent activation. The ultraviolet light source 41 is thereforedisposed at a position corresponding to the second edge 75.

In this way, according to the invention, the illumination light source15 and the ultraviolet light source 41 are separately arranged in anappropriate way while the relationship between deformation of thedocument and the specular reflection condition is taken intoconsideration. As a result, image capturing in the specular reflectioncondition can be avoided when the document is deformed, while the sizeof device can be reduced.

Further, in the embodiment, the illumination light source 15 may includeboth a white light source 31 and an infrared light source 21, and thevisible light source 31 may be located farther away from the surface tobe read in the vertical direction than the infrared light source 21.Since the infrared light source 21 is located closer to the surface tobe read, a larger area can be illuminated even with the infrared lightsource that has a narrow radiation angle, and readability can beassured. In addition, since the visible light source 31 is located awayfrom the surface to be read, the difference between the distance fromone location on the surface to be read to the visible light source 31and the distance from another location to the visible light source 31 isreduced, so that unevenness of illumination is also reduced and a gooddisplay image can be obtained. Therefore, a document reading device 1can be provided, which is provided with a visible light source 31, aninfrared light source 21, and an ultraviolet light source 41, and canavoid image capturing in the specular reflection condition when thedocument is deformed, while the size of the device can be reduced andthe device is capable of appropriately providing both visible andinfrared light illumination.

Further, in the embodiment, the imaging unit has a UV cut filter. Withthis configuration, ultraviolet light reflecting or otherwise comingfrom the ultraviolet light source can be prevented from entering theimaging unit, and image quality obtained by the imaging unit can beimproved.

Preferred embodiments according to the present invention have beendescribed. The present invention, however, is not limited to the aboveembodiments and those skilled in the art can off course make variousmodifications to the above embodiments within the scope of theinvention.

Although currently possible preferred embodiments of the invention havebeen described above, it is understood that various modifications can bemade to the embodiments and it is intended that all such modificationsthat fall within the true spirit and scope of the invention are coveredby the attached claims.

INDUSTRIAL APPLICABILITY

As described above, a document reading device according to the inventionprovides an advantage of being capable of avoiding image capturing inthe specular reflection condition when the document is deformed, whilethe size of the device can be reduced, and is useful for a passportreader, for example.

REFERENCE SIGNS LIST

-   1 Document reading device-   5 Mounting surface-   7 Passport-   9 Page to be read-   11 Mirror-   13 Camera-   15 Illumination light source-   21 Infrared light source-   22 Infrared LED array-   25 a-25 e Infrared LED-   31 White light source-   32 White LED array-   35 a-35 f White LED-   41 Ultraviolet light source-   43 Ultraviolet LED array-   45 a-451 Ultraviolet LED-   63 Code-   65 Fluorescent pattern-   71 Binding edge-   73 First edge-   75 Second edge

The invention claimed is:
 1. A document reading device comprising: adocument placing unit on which a surface to be read of a document isplaced, the document being composed of a plurality of sheets bound at abinding edge; an imaging unit which takes an image of the surface to beread; an illumination light source which radiates illumination light toilluminate the surface to be read; an ultraviolet light source whichradiates ultraviolet light to activate a fluorescent material on thesurface to be read; wherein the illumination light source is located ata position corresponding to a first edge perpendicular to the bindingedge on the surface to be read and arranged to radiate illuminationlight toward the surface to be read in a direction intersecting with thefirst edge, and the ultraviolet light source is located at a positioncorresponding to a second edge parallel to the binding edge on thesurface to be read and arranged to radiate ultraviolet light toward thesurface to be read in a direction intersecting with the second edge. 2.The document reading device according to claim 1, wherein theillumination light source includes a visible light source.
 3. Thedocument reading device according to claim 1, wherein the illuminationlight source includes an infrared light source.
 4. The document readingdevice according to claim 1, wherein the illumination light sourceincludes both a visible light source and an infrared light source, andthe visible light source is located farther away from the surface to beread in the vertical direction than the infrared light source.
 5. Thedocument reading device according to claim 1, wherein the imaging unithas a UV cut filter.